/*
 * 86Box    A hypervisor and IBM PC system emulator that specializes in
 *          running old operating systems and software designed for IBM
 *          PC systems and compatibles from 1981 through fairly recent
 *          system designs based on the PCI bus.
 *
 *          This file is part of the 86Box distribution.
 *
 *          3DFX Voodoo emulation.
 *
 *
 *
 * Authors: Sarah Walker, <https://pcem-emulator.co.uk/>
 *
 *          Copyright 2008-2020 Sarah Walker.
 */
#include <assert.h>
#include <stdarg.h>
#include <stdio.h>
#include <stdint.h>
#include <string.h>
#include <stdlib.h>
#include <stddef.h>
#include <wchar.h>
#include <math.h>
#define HAVE_STDARG_H
#include <86box/86box.h>
#include "cpu.h"
#include <86box/machine.h>
#include <86box/device.h>
#include <86box/mem.h>
#include <86box/timer.h>
#include <86box/device.h>
#include <86box/plat.h>
#include <86box/thread.h>
#include <86box/video.h>
#include <86box/vid_svga.h>
#include <86box/vid_voodoo_common.h>
#include <86box/vid_voodoo_display.h>
#include <86box/vid_voodoo_regs.h>
#include <86box/vid_voodoo_render.h>

#ifdef ENABLE_VOODOODISP_LOG
int voodoodisp_do_log = ENABLE_VOODOODISP_LOG;

static void
voodoodisp_log(const char *fmt, ...)
{
    va_list ap;

    if (voodoodisp_do_log) {
        va_start(ap, fmt);
        pclog_ex(fmt, ap);
        va_end(ap);
    }
}
#else
#    define voodoodisp_log(fmt, ...)
#endif

void
voodoo_update_ncc(voodoo_t *voodoo, int tmu)
{
    for (uint8_t tbl = 0; tbl < 2; tbl++) {
        for (uint16_t col = 0; col < 256; col++) {
            int y = (col >> 4);
            int i = (col >> 2) & 3;
            int q = col & 3;
            int i_r;
            int i_g;
            int i_b;
            int q_r;
            int q_g;
            int q_b;

            y = (voodoo->nccTable[tmu][tbl].y[y >> 2] >> ((y & 3) * 8)) & 0xff;

            i_r = (voodoo->nccTable[tmu][tbl].i[i] >> 18) & 0x1ff;
            if (i_r & 0x100)
                i_r |= 0xfffffe00;
            i_g = (voodoo->nccTable[tmu][tbl].i[i] >> 9) & 0x1ff;
            if (i_g & 0x100)
                i_g |= 0xfffffe00;
            i_b = voodoo->nccTable[tmu][tbl].i[i] & 0x1ff;
            if (i_b & 0x100)
                i_b |= 0xfffffe00;

            q_r = (voodoo->nccTable[tmu][tbl].q[q] >> 18) & 0x1ff;
            if (q_r & 0x100)
                q_r |= 0xfffffe00;
            q_g = (voodoo->nccTable[tmu][tbl].q[q] >> 9) & 0x1ff;
            if (q_g & 0x100)
                q_g |= 0xfffffe00;
            q_b = voodoo->nccTable[tmu][tbl].q[q] & 0x1ff;
            if (q_b & 0x100)
                q_b |= 0xfffffe00;

            voodoo->ncc_lookup[tmu][tbl][col].rgba.r = CLAMP(y + i_r + q_r);
            voodoo->ncc_lookup[tmu][tbl][col].rgba.g = CLAMP(y + i_g + q_g);
            voodoo->ncc_lookup[tmu][tbl][col].rgba.b = CLAMP(y + i_b + q_b);
            voodoo->ncc_lookup[tmu][tbl][col].rgba.a = 0xff;
        }
    }
}

void
voodoo_pixelclock_update(voodoo_t *voodoo)
{
    int    m  = (voodoo->dac_pll_regs[0] & 0x7f) + 2;
    int    n1 = ((voodoo->dac_pll_regs[0] >> 8) & 0x1f) + 2;
    int    n2 = ((voodoo->dac_pll_regs[0] >> 13) & 0x07);
    float  t  = (14318184.0 * ((float) m / (float) n1)) / (float) (1 << n2);
    double clock_const;
    int    line_length;

    if ((voodoo->dac_data[6] & 0xf0) == 0x20 || (voodoo->dac_data[6] & 0xf0) == 0x60 || (voodoo->dac_data[6] & 0xf0) == 0x70)
        t /= 2.0f;

    line_length = (voodoo->hSync & 0xff) + ((voodoo->hSync >> 16) & 0x3ff);

    //        voodoodisp_log("Pixel clock %f MHz hsync %08x line_length %d\n", t, voodoo->hSync, line_length);

    voodoo->pixel_clock = t;

    clock_const       = cpuclock / t;
    voodoo->line_time = (uint64_t) ((double) line_length * clock_const * (double) (1ULL << 32));
}

static void
voodoo_calc_clutData(voodoo_t *voodoo)
{
    int c;

    for (c = 0; c < 256; c++) {
        voodoo->clutData256[c].r = (voodoo->clutData[c >> 3].r * (8 - (c & 7)) + voodoo->clutData[(c >> 3) + 1].r * (c & 7)) >> 3;
        voodoo->clutData256[c].g = (voodoo->clutData[c >> 3].g * (8 - (c & 7)) + voodoo->clutData[(c >> 3) + 1].g * (c & 7)) >> 3;
        voodoo->clutData256[c].b = (voodoo->clutData[c >> 3].b * (8 - (c & 7)) + voodoo->clutData[(c >> 3) + 1].b * (c & 7)) >> 3;
    }

    for (c = 0; c < 65536; c++) {
        int r = (c >> 8) & 0xf8;
        int g = (c >> 3) & 0xfc;
        int b = (c << 3) & 0xf8;
#if 0
        r |= (r >> 5);
        g |= (g >> 6);
        b |= (b >> 5);
#endif
        voodoo->video_16to32[c] = (voodoo->clutData256[r].r << 16) | (voodoo->clutData256[g].g << 8) | voodoo->clutData256[b].b;
    }
}

#define FILTDIV 256

static int FILTCAP;
static int FILTCAPG;
static int FILTCAPB = 0; /* color filter threshold values */

void
voodoo_generate_filter_v1(voodoo_t *voodoo)
{
    float difference;
    float diffg;
    float diffb;
    float thiscol;
    float thiscolg;
    float thiscolb;
    float lined;
    float fcr;
    float fcg;
    float fcb;

    fcr = FILTCAP * 5;
    fcg = FILTCAPG * 6;
    fcb = FILTCAPB * 5;

    for (uint16_t g = 0; g < FILTDIV; g++) // pixel 1
    {
        for (uint16_t h = 0; h < FILTDIV; h++) // pixel 2
        {
            difference = (float) (h - g);
            diffg      = difference;
            diffb      = difference;

            thiscol = thiscolg = thiscolb = g;

            if (difference > FILTCAP)
                difference = FILTCAP;
            if (difference < -FILTCAP)
                difference = -FILTCAP;

            if (diffg > FILTCAPG)
                diffg = FILTCAPG;
            if (diffg < -FILTCAPG)
                diffg = -FILTCAPG;

            if (diffb > FILTCAPB)
                diffb = FILTCAPB;
            if (diffb < -FILTCAPB)
                diffb = -FILTCAPB;

            // hack - to make it not bleed onto black
            // if (g == 0){
            // difference = diffg = diffb = 0;
            //}

            if ((difference < fcr) || (-difference > -fcr))
                thiscol = g + (difference / 2);
            if ((diffg < fcg) || (-diffg > -fcg))
                thiscolg = g + (diffg / 2); /* need these divides so we can actually undither! */
            if ((diffb < fcb) || (-diffb > -fcb))
                thiscolb = g + (diffb / 2);

            if (thiscol < 0)
                thiscol = 0;
            if (thiscol > FILTDIV - 1)
                thiscol = FILTDIV - 1;

            if (thiscolg < 0)
                thiscolg = 0;
            if (thiscolg > FILTDIV - 1)
                thiscolg = FILTDIV - 1;

            if (thiscolb < 0)
                thiscolb = 0;
            if (thiscolb > FILTDIV - 1)
                thiscolb = FILTDIV - 1;

            voodoo->thefilter[g][h]  = thiscol;
            voodoo->thefilterg[g][h] = thiscolg;
            voodoo->thefilterb[g][h] = thiscolb;
        }

        lined = g + 4;
        if (lined > 255)
            lined = 255;
        voodoo->purpleline[g][0] = lined;
        voodoo->purpleline[g][2] = lined;

        lined = g + 0;
        if (lined > 255)
            lined = 255;
        voodoo->purpleline[g][1] = lined;
    }
}

void
voodoo_generate_filter_v2(voodoo_t *voodoo)
{
    float difference;
    float thiscol;
    float thiscolg;
    float thiscolb;
    float clr;
    float clg;
    float clb = 0;
    float fcr;
    float fcg;
    float fcb = 0;

    // pre-clamping

    fcr = FILTCAP;
    fcg = FILTCAPG;
    fcb = FILTCAPB;

    if (fcr > 32)
        fcr = 32;
    if (fcg > 32)
        fcg = 32;
    if (fcb > 32)
        fcb = 32;

    for (uint16_t g = 0; g < 256; g++) // pixel 1 - our target pixel we want to bleed into
    {
        for (uint16_t h = 0; h < 256; h++) // pixel 2 - our main pixel
        {
            float avg;
            float avgdiff;

            difference = (float) (g - h);
            avg        = (float) ((g + g + g + g + h) / 5);
            avgdiff    = avg - (float) ((g + h + h + h + h) / 5);
            if (avgdiff < 0)
                avgdiff *= -1;
            if (difference < 0)
                difference *= -1;

            thiscol = thiscolg = thiscolb = g;

            // try lighten
            if (h > g) {
                clr = clg = clb = avgdiff;

                if (clr > fcr)
                    clr = fcr;
                if (clg > fcg)
                    clg = fcg;
                if (clb > fcb)
                    clb = fcb;

                thiscol  = g + clr;
                thiscolg = g + clg;
                thiscolb = g + clb;

                if (thiscol > g + FILTCAP)
                    thiscol = g + FILTCAP;
                if (thiscolg > g + FILTCAPG)
                    thiscolg = g + FILTCAPG;
                if (thiscolb > g + FILTCAPB)
                    thiscolb = g + FILTCAPB;

                if (thiscol > g + avgdiff)
                    thiscol = g + avgdiff;
                if (thiscolg > g + avgdiff)
                    thiscolg = g + avgdiff;
                if (thiscolb > g + avgdiff)
                    thiscolb = g + avgdiff;
            }

            if (difference > FILTCAP)
                thiscol = g;
            if (difference > FILTCAPG)
                thiscolg = g;
            if (difference > FILTCAPB)
                thiscolb = g;

            // clamp
            if (thiscol < 0)
                thiscol = 0;
            if (thiscolg < 0)
                thiscolg = 0;
            if (thiscolb < 0)
                thiscolb = 0;

            if (thiscol > 255)
                thiscol = 255;
            if (thiscolg > 255)
                thiscolg = 255;
            if (thiscolb > 255)
                thiscolb = 255;

            // add to the table
            voodoo->thefilter[g][h]  = thiscol;
            voodoo->thefilterg[g][h] = thiscolg;
            voodoo->thefilterb[g][h] = thiscolb;

            // debug the ones that don't give us much of a difference
            // if (difference < FILTCAP)
            // voodoodisp_log("Voodoofilter: %ix%i - %f difference, %f average difference, R=%f, G=%f, B=%f\n", g, h, difference, avgdiff, thiscol, thiscolg, thiscolb);
        }
    }
}

void
voodoo_threshold_check(voodoo_t *voodoo)
{
    int r;
    int g;
    int b;

    if (!voodoo->scrfilterEnabled)
        return; /* considered disabled; don't check and generate */

    /* Check for changes, to generate anew table */
    if (voodoo->scrfilterThreshold != voodoo->scrfilterThresholdOld) {
        r = (voodoo->scrfilterThreshold >> 16) & 0xFF;
        g = (voodoo->scrfilterThreshold >> 8) & 0xFF;
        b = voodoo->scrfilterThreshold & 0xFF;

        FILTCAP  = r;
        FILTCAPG = g;
        FILTCAPB = b;

        voodoodisp_log("Voodoo Filter Threshold Check: %06x - RED %i GREEN %i BLUE %i\n", voodoo->scrfilterThreshold, r, g, b);

        voodoo->scrfilterThresholdOld = voodoo->scrfilterThreshold;

        if (voodoo->type == VOODOO_2)
            voodoo_generate_filter_v2(voodoo);
        else
            voodoo_generate_filter_v1(voodoo);

        if (voodoo->type >= VOODOO_BANSHEE)
            voodoo_generate_vb_filters(voodoo, FILTCAP, FILTCAPG);
    }
}

static void
voodoo_filterline_v1(voodoo_t *voodoo, uint8_t *fil, int column, uint16_t *src, int line)
{
    // Scratchpad for avoiding feedback streaks
    uint8_t fil3[4096 * 3];

    assert(voodoo->h_disp <= 4096);
    /* 16 to 32-bit */
    for (int x = 0; x < column; x++) {
        fil[x * 3]     = ((src[x] & 31) << 3);
        fil[x * 3 + 1] = (((src[x] >> 5) & 63) << 2);
        fil[x * 3 + 2] = (((src[x] >> 11) & 31) << 3);

        // Copy to our scratchpads
        fil3[x * 3 + 0] = fil[x * 3 + 0];
        fil3[x * 3 + 1] = fil[x * 3 + 1];
        fil3[x * 3 + 2] = fil[x * 3 + 2];
    }

    /* lines */

    if (line & 1) {
        for (int x = 0; x < column; x++) {
            fil[x * 3]     = voodoo->purpleline[fil[x * 3]][0];
            fil[x * 3 + 1] = voodoo->purpleline[fil[x * 3 + 1]][1];
            fil[x * 3 + 2] = voodoo->purpleline[fil[x * 3 + 2]][2];
        }
    }

    /* filtering time */

    for (int x = 1; x < column; x++) {
        fil3[x * 3]     = voodoo->thefilterb[fil[x * 3]][fil[(x - 1) * 3]];
        fil3[x * 3 + 1] = voodoo->thefilterg[fil[x * 3 + 1]][fil[(x - 1) * 3 + 1]];
        fil3[x * 3 + 2] = voodoo->thefilter[fil[x * 3 + 2]][fil[(x - 1) * 3 + 2]];
    }

    for (int x = 1; x < column; x++) {
        fil[x * 3]     = voodoo->thefilterb[fil3[x * 3]][fil3[(x - 1) * 3]];
        fil[x * 3 + 1] = voodoo->thefilterg[fil3[x * 3 + 1]][fil3[(x - 1) * 3 + 1]];
        fil[x * 3 + 2] = voodoo->thefilter[fil3[x * 3 + 2]][fil3[(x - 1) * 3 + 2]];
    }

    for (int x = 1; x < column; x++) {
        fil3[x * 3]     = voodoo->thefilterb[fil[x * 3]][fil[(x - 1) * 3]];
        fil3[x * 3 + 1] = voodoo->thefilterg[fil[x * 3 + 1]][fil[(x - 1) * 3 + 1]];
        fil3[x * 3 + 2] = voodoo->thefilter[fil[x * 3 + 2]][fil[(x - 1) * 3 + 2]];
    }

    for (int x = 0; x < column - 1; x++) {
        fil[x * 3]     = voodoo->thefilterb[fil3[x * 3]][fil3[(x + 1) * 3]];
        fil[x * 3 + 1] = voodoo->thefilterg[fil3[x * 3 + 1]][fil3[(x + 1) * 3 + 1]];
        fil[x * 3 + 2] = voodoo->thefilter[fil3[x * 3 + 2]][fil3[(x + 1) * 3 + 2]];
    }
}

static void
voodoo_filterline_v2(voodoo_t *voodoo, uint8_t *fil, int column, uint16_t *src, UNUSED(int line))
{
    int x;

    // Scratchpad for blending filter
    uint8_t fil3[4096 * 3];

    assert(voodoo->h_disp <= 4096);
    /* 16 to 32-bit */
    for (x = 0; x < column; x++) {
        // Blank scratchpads
        fil3[x * 3 + 0] = fil[x * 3 + 0] = ((src[x] & 31) << 3);
        fil3[x * 3 + 1] = fil[x * 3 + 1] = (((src[x] >> 5) & 63) << 2);
        fil3[x * 3 + 2] = fil[x * 3 + 2] = (((src[x] >> 11) & 31) << 3);
    }

    /* filtering time */

    for (x = 1; x < column - 3; x++) {
        fil3[(x + 3) * 3]     = voodoo->thefilterb[(src[x + 3] & 31) << 3][(src[x] & 31) << 3];
        fil3[(x + 3) * 3 + 1] = voodoo->thefilterg[((src[x + 3] >> 5) & 63) << 2][((src[x] >> 5) & 63) << 2];
        fil3[(x + 3) * 3 + 2] = voodoo->thefilter[((src[x + 3] >> 11) & 31) << 3][((src[x] >> 11) & 31) << 3];

        fil[(x + 2) * 3]     = voodoo->thefilterb[fil3[(x + 2) * 3]][(src[x] & 31) << 3];
        fil[(x + 2) * 3 + 1] = voodoo->thefilterg[fil3[(x + 2) * 3 + 1]][((src[x] >> 5) & 63) << 2];
        fil[(x + 2) * 3 + 2] = voodoo->thefilter[fil3[(x + 2) * 3 + 2]][((src[x] >> 11) & 31) << 3];

        fil3[(x + 1) * 3]     = voodoo->thefilterb[fil[(x + 1) * 3]][(src[x] & 31) << 3];
        fil3[(x + 1) * 3 + 1] = voodoo->thefilterg[fil[(x + 1) * 3 + 1]][((src[x] >> 5) & 63) << 2];
        fil3[(x + 1) * 3 + 2] = voodoo->thefilter[fil[(x + 1) * 3 + 2]][((src[x] >> 11) & 31) << 3];

        fil[(x - 1) * 3]     = voodoo->thefilterb[fil3[(x - 1) * 3]][(src[x] & 31) << 3];
        fil[(x - 1) * 3 + 1] = voodoo->thefilterg[fil3[(x - 1) * 3 + 1]][((src[x] >> 5) & 63) << 2];
        fil[(x - 1) * 3 + 2] = voodoo->thefilter[fil3[(x - 1) * 3 + 2]][((src[x] >> 11) & 31) << 3];
    }

    // unroll for edge cases

    fil3[(column - 3) * 3]     = voodoo->thefilterb[(src[column - 3] & 31) << 3][(src[column] & 31) << 3];
    fil3[(column - 3) * 3 + 1] = voodoo->thefilterg[((src[column - 3] >> 5) & 63) << 2][((src[column] >> 5) & 63) << 2];
    fil3[(column - 3) * 3 + 2] = voodoo->thefilter[((src[column - 3] >> 11) & 31) << 3][((src[column] >> 11) & 31) << 3];

    fil3[(column - 2) * 3]     = voodoo->thefilterb[(src[column - 2] & 31) << 3][(src[column] & 31) << 3];
    fil3[(column - 2) * 3 + 1] = voodoo->thefilterg[((src[column - 2] >> 5) & 63) << 2][((src[column] >> 5) & 63) << 2];
    fil3[(column - 2) * 3 + 2] = voodoo->thefilter[((src[column - 2] >> 11) & 31) << 3][((src[column] >> 11) & 31) << 3];

    fil3[(column - 1) * 3]     = voodoo->thefilterb[(src[column - 1] & 31) << 3][(src[column] & 31) << 3];
    fil3[(column - 1) * 3 + 1] = voodoo->thefilterg[((src[column - 1] >> 5) & 63) << 2][((src[column] >> 5) & 63) << 2];
    fil3[(column - 1) * 3 + 2] = voodoo->thefilter[((src[column - 1] >> 11) & 31) << 3][((src[column] >> 11) & 31) << 3];

    fil[(column - 2) * 3]     = voodoo->thefilterb[fil3[(column - 2) * 3]][(src[column] & 31) << 3];
    fil[(column - 2) * 3 + 1] = voodoo->thefilterg[fil3[(column - 2) * 3 + 1]][((src[column] >> 5) & 63) << 2];
    fil[(column - 2) * 3 + 2] = voodoo->thefilter[fil3[(column - 2) * 3 + 2]][((src[column] >> 11) & 31) << 3];

    fil[(column - 1) * 3]     = voodoo->thefilterb[fil3[(column - 1) * 3]][(src[column] & 31) << 3];
    fil[(column - 1) * 3 + 1] = voodoo->thefilterg[fil3[(column - 1) * 3 + 1]][((src[column] >> 5) & 63) << 2];
    fil[(column - 1) * 3 + 2] = voodoo->thefilter[fil3[(column - 1) * 3 + 2]][((src[column] >> 11) & 31) << 3];

    fil3[(column - 1) * 3]     = voodoo->thefilterb[fil[(column - 1) * 3]][(src[column] & 31) << 3];
    fil3[(column - 1) * 3 + 1] = voodoo->thefilterg[fil[(column - 1) * 3 + 1]][((src[column] >> 5) & 63) << 2];
    fil3[(column - 1) * 3 + 2] = voodoo->thefilter[fil[(column - 1) * 3 + 2]][((src[column] >> 11) & 31) << 3];
}

void
voodoo_callback(void *priv)
{
    voodoo_t        *voodoo  = (voodoo_t *) priv;
    const monitor_t *monitor = &monitors[voodoo->monitor_index];

    if (voodoo->fbiInit0 & FBIINIT0_VGA_PASS) {
        if (voodoo->line < voodoo->v_disp) {
            voodoo_t *draw_voodoo;
            int       draw_line;

            if (SLI_ENABLED) {
                if (voodoo == voodoo->set->voodoos[1])
                    goto skip_draw;

                if (((voodoo->initEnable & INITENABLE_SLI_MASTER_SLAVE) ? 1 : 0) == (voodoo->line & 1))
                    draw_voodoo = voodoo;
                else
                    draw_voodoo = voodoo->set->voodoos[1];
                draw_line = voodoo->line >> 1;
            } else {
                if (!(voodoo->fbiInit0 & 1))
                    goto skip_draw;
                draw_voodoo = voodoo;
                draw_line   = voodoo->line;
            }

            if (draw_voodoo->dirty_line[draw_line]) {
                uint32_t *p   = &monitor->target_buffer->line[voodoo->line + 8][8];
                uint16_t *src = (uint16_t *) &draw_voodoo->fb_mem[draw_voodoo->front_offset + draw_line * draw_voodoo->row_width];
                int       x;

                draw_voodoo->dirty_line[draw_line] = 0;

                if (voodoo->line < voodoo->dirty_line_low) {
                    voodoo->dirty_line_low = voodoo->line;
                    video_wait_for_buffer_monitor(voodoo->monitor_index);
                }
                if (voodoo->line > voodoo->dirty_line_high)
                    voodoo->dirty_line_high = voodoo->line;

                /* Draw left overscan. */
                for (x = 0; x < 8; x++)
                    monitor->target_buffer->line[voodoo->line + 8][x] = 0x00000000;

                if (voodoo->scrfilter && voodoo->scrfilterEnabled) {
                    uint8_t fil[4096 * 3]; /* interleaved 24-bit RGB */

                    assert(voodoo->h_disp <= 4096);
                    if (voodoo->type == VOODOO_2)
                        voodoo_filterline_v2(voodoo, fil, voodoo->h_disp, src, voodoo->line);
                    else
                        voodoo_filterline_v1(voodoo, fil, voodoo->h_disp, src, voodoo->line);

                    for (x = 0; x < voodoo->h_disp; x++) {
                        p[x] = (voodoo->clutData256[fil[x * 3]].b << 0 | voodoo->clutData256[fil[x * 3 + 1]].g << 8 | voodoo->clutData256[fil[x * 3 + 2]].r << 16);
                    }
                } else {
                    for (x = 0; x < voodoo->h_disp; x++) {
                        p[x] = draw_voodoo->video_16to32[src[x]];
                    }
                }

                /* Draw right overscan. */
                for (x = 0; x < 8; x++)
                    monitor->target_buffer->line[voodoo->line + 8][voodoo->h_disp + x + 8] = 0x00000000;
            }
        }
    }
skip_draw:
    if (voodoo->line == voodoo->v_disp) {
#if 0
        voodoodisp_log("retrace %i %i %08x %i\n", voodoo->retrace_count, voodoo->swap_interval, voodoo->swap_offset, voodoo->swap_pending);
#endif
        voodoo->retrace_count++;
        if (SLI_ENABLED && (voodoo->fbiInit2 & FBIINIT2_SWAP_ALGORITHM_MASK) == FBIINIT2_SWAP_ALGORITHM_SLI_SYNC) {
            if (voodoo == voodoo->set->voodoos[0]) {
                voodoo_t *voodoo_1 = voodoo->set->voodoos[1];

                thread_wait_mutex(voodoo->swap_mutex);
                /*Only swap if both Voodoos are waiting for buffer swap*/
                if (voodoo->swap_pending && (voodoo->retrace_count > voodoo->swap_interval) && voodoo_1->swap_pending && (voodoo_1->retrace_count > voodoo_1->swap_interval)) {
                    memset(voodoo->dirty_line, 1, 1024);
                    voodoo->retrace_count = 0;
                    voodoo->front_offset  = voodoo->swap_offset;
                    if (voodoo->swap_count > 0)
                        voodoo->swap_count--;
                    voodoo->swap_pending = 0;

                    memset(voodoo_1->dirty_line, 1, 1024);
                    voodoo_1->retrace_count = 0;
                    voodoo_1->front_offset  = voodoo_1->swap_offset;
                    if (voodoo_1->swap_count > 0)
                        voodoo_1->swap_count--;
                    voodoo_1->swap_pending = 0;
                    thread_release_mutex(voodoo->swap_mutex);

                    thread_set_event(voodoo->wake_fifo_thread);
                    thread_set_event(voodoo_1->wake_fifo_thread);

                    voodoo->frame_count++;
                    voodoo_1->frame_count++;
                } else
                    thread_release_mutex(voodoo->swap_mutex);
            }
        } else {
            thread_wait_mutex(voodoo->swap_mutex);
            if (voodoo->swap_pending && (voodoo->retrace_count > voodoo->swap_interval)) {
                voodoo->front_offset = voodoo->swap_offset;
                if (voodoo->swap_count > 0)
                    voodoo->swap_count--;
                voodoo->swap_pending = 0;
                thread_release_mutex(voodoo->swap_mutex);

                memset(voodoo->dirty_line, 1, 1024);
                voodoo->retrace_count = 0;
                thread_set_event(voodoo->wake_fifo_thread);
                voodoo->frame_count++;
            } else
                thread_release_mutex(voodoo->swap_mutex);
        }
        voodoo->v_retrace = 1;
    }
    voodoo->line++;

    if (voodoo->fbiInit0 & FBIINIT0_VGA_PASS) {
        if (voodoo->line == voodoo->v_disp) {
            int force_blit = 0;
            thread_wait_mutex(voodoo->force_blit_mutex);
            if (voodoo->force_blit_count) {
                force_blit = 1;
                if (--voodoo->force_blit_count < 0)
                    voodoo->force_blit_count = 0;
            }
            thread_release_mutex(voodoo->force_blit_mutex);

            if (voodoo->dirty_line_high > voodoo->dirty_line_low || force_blit)
                svga_doblit(voodoo->h_disp, voodoo->v_disp - 1, voodoo->svga);
            if (voodoo->clutData_dirty) {
                voodoo->clutData_dirty = 0;
                voodoo_calc_clutData(voodoo);
            }
            voodoo->dirty_line_high = -1;
            voodoo->dirty_line_low  = 2000;
        }
    }

    if (voodoo->line >= voodoo->v_total) {
        voodoo->line      = 0;
        voodoo->v_retrace = 0;
    }
    if (voodoo->line_time)
        timer_advance_u64(&voodoo->timer, voodoo->line_time);
    else
        timer_advance_u64(&voodoo->timer, TIMER_USEC * 32);
}
